Collaborative Research: Mathematical Analysis of Certain Geophysical and Fluid Dynamics Models

合作研究：某些地球物理和流体动力学模型的数学分析

• 批准号: 1109640
• 负责人: Edriss Titi
• 金额: $ 38.56万
• 依托单位: University of California-Irvine
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-10-01 至 2015-09-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1109640&HistoricalAwards=false
• 关键词: Collaborative; Research; Mathematical; Analysis; Certain

Titi, DMS-1109640Cao, DMS-1109022 Numerical ocean modeling is computationally very demanding. Traditionally, the hydrostatic approximation balance, in the vertical momentum equation, has been applied to reduce the computational burden. Recently, the investigators have made significant progress in the rigorous understanding of the properties of the solutions to these models. However, it is still impossible to use present computing resources to simulate this large system for the wide range of spatial and temporal scales. Therefore, there is a need to further simplify these models to focus on understanding and simulating certain localized smaller-scale phenomena, such as the geostrophic adjustment of frontal anomalies in a rotating continuously stratified fluid of strictly rectilinear fronts and jets, and rapidly rotating convection which, according to the Taylor-Proudman constraint, takes place in tall columnar structures. The development of fast, accurate, and reliable numerical models of the climate system is key to understanding and predicting the magnitude and distribution of future climate variability. The focus of this project is to provide rigorous justification to these simplified models of the dynamics of the atmosphere and the oceans, and to investigate their long-term behavior. The investigators study the questions of existence, uniqueness, and continuous dependence on the initial data of the solutions to these models. This is the first, and the most crucial step, in justifying the derivation of these models and their consistency with the physical observations. There are numerous governing equations to fully describe the dynamics of climate. It is impossible to use present computing resources to simulate this large system for the wide range of spatial and temporal scales. Indeed, in order to understand, for example, the mechanism of atmospheric and oceanic turbulence, and to properly predict the climate, it is necessary to provide simplified and reliable models that contain the main features of the underlying physical phenomena. The investigators focus on the development of novel, theoretical and computational, mathematical tools for investigating these simplified models, and on justifying their derivation in order to enhance our understanding of fluid dynamics models and the climate system and its predictability. The training of undergraduate and graduate students with analytical and computational skills is also achieved through this study.

DMS-1109022海洋数值模拟的计算要求非常高。传统上，在垂直动量方程中采用流体静力近似平衡来减少计算量。最近，研究人员在严格理解这些模型的解的性质方面取得了重大进展。然而，利用现有的计算资源在大范围的空间和时间尺度上模拟这个大系统仍然是不可能的。因此，需要进一步简化这些模型，重点理解和模拟某些局部的小尺度现象，如严格直线锋和射流的旋转连续分层流体中锋面异常的地转调整，以及根据Taylor-Proudman约束发生在高柱状结构中的快速旋转对流。发展快速、准确和可靠的气候系统数值模式是理解和预测未来气候变率的大小和分布的关键。这个项目的重点是为这些简化的大气和海洋动力学模型提供严格的理由，并调查它们的长期行为。研究人员研究了这些模型的解的初始数据的存在性、唯一性和连续依赖性问题。这是证明这些模型的推导及其与物理观测的一致性的第一步，也是最关键的一步。有许多控制方程可以完全描述气候动力学。利用现有的计算资源不可能在大范围的空间和时间尺度上模拟这个大系统。事实上，为了理解，例如，大气和海洋湍流的机制，并正确地预测气候，有必要提供包含潜在物理现象的主要特征的简化和可靠的模式。研究人员专注于研究这些简化模型的新颖理论和计算数学工具的发展，并证明其推导的合理性，以提高我们对流体动力学模型和气候系统及其可预测性的理解。通过本课程的学习，还可以培养本科生和研究生的分析和计算能力。